US2827827A

US2827827A - Planetarium projector

Info

Publication number: US2827827A
Application number: US483547A
Authority: US
Inventors: Armand N Spitz
Original assignee: Individual
Current assignee: Individual
Priority date: 1955-01-24
Filing date: 1955-01-24
Publication date: 1958-03-25
Anticipated expiration: 1975-03-25

Description

March 25, 1958 V A. N. s'PlTz 2,827,827

' PLANETARIUM PROJECTOR Filed Jan. 24. 1955 4 Sheets-Sheet 1 F INVENTOR.

ARMANI) N. SPI TZ ATTORNEYS Filed Jan. 24, 1955 March 25, 1958 2,827,827

A. N. SPITZ PLANETARIUM PROJECTOR 4 Sheets-Sheet 2 N m z :2

in Q N g O o U. Q g '3 INVENTOR.

f ARMAND N. SPITZ ATTORNEYS .March 25, 1958 SPITZ 2,827,827

PLANETARIUM PROJECTOR Filed Jan. 24, 1955 4 Sheets-Sheet 3 FHG. 5.

INVEN TOR. eRMAND N. SPITZ FIG. 4. flag,

ATTORNEYS i A. N. sPrrz PLANETARIUM PROJECTOR March 25, 1958 4 Sheets-Sheet 4 Filed Jan. 24, 1955 F I GT? FIG. 6.

INVENTOR- ARMAND- N. SPITZ l jzw'wl h I ATTORNEY;

ttes

This invention relates to a planetarium and has particular reference to the provision of improved star projecting means therefor. n I V W As disclosed in my Patent No. 2,632,359, dated March 24, I953, acceptable projection of star images may be secured by the projection oflight through pinholes in a 'globe from a source presenting a small area of light to the pinholes. This very simpleprojection arrangement is in sharp contrast with the elaborate projection systems generally used heretofore in planetaria. Pihhole projection, however, hasthe drawback that if very small size star images are to be produced, they cannot be satisfactorily attained through the use of known filament lamps of sufiicient intensity. If a filament lamp is used as the source, the image is essentially that of the filament itself. The image is proportional to the size of the filament, other conditions being the same, and because of the requirements of heat dissipation, the necessary area presented by the filament increases with intensity of illumination. If the radius of the dome on which projection takes place is small, the filament image produced thereon is small. However, if a large'siz'e dome is involved, an inadequately bright image: results fro'ih the use of a filament lamp having a sufiieiently small filament to provide an image which is not too large. Up to a' certain limit, in the darkness involved ina'planetarium enclosure, the human eye is relatively insensitive to the shape of the projected image, being incapable of distinguishing from a reasonable viewing distance whether the spot of light which is seen is a pointor a small area; Consequently, in accordance ;with' my patent, referred to above, it has been possible, in' small planetaria, tosecure highly satisfactory results by utilizing the smallest available filaments and small size pinholes when the dome receiving the imageswas of reasonably small radius.

In such case, differentiation between stars "of dilierent magnitudes was readily accomplished merely by changing the sizes of the pinholes to cause them to pa'ssmor'e or less light,: the limitation on size being merely that of keeping within bounds thesize of the spot of light produced; A large spot of the same intensity per unit area as a small spot appears brighter to the eye and, hence,- satisfactory differentiation of the stars as to their magnitudes was achieved. Another drawback to a'filament source of light-is that it will not, in general, radiate the same intensity of illumination in all directions. This results from the fact that the filament must generally be curved or in the'form of a helix in order to provide ample intensity ofillumination. Because of heat dissipatioii reqnirements such a filament cannot be made to provide equal intensityofillumination in all necessary'directions. An'lattemp't to equalize the illuminationleads to a requirement of a larger presented filament area which is; in turn, detrimental to the image produced, both causing it to be larger and of recognizable-shape;

The p'r'esent'inventionis concerned with the provision of a projection system which overcomes the drawbacks or the simple type of system just referred to while,- at the atent C 2,827,827 l atented Mar. 25, 1958 same time, permitting the simplicity of pinhole piojection or inexpensive variations thereof. Briefly suminarized, there isu'sed in accordance with the invention a highly intense arc-type source of light which may itself be highly directional in it's illuminating characteristics. A beaih of light from'such'a source is projected upon a small spherical mirror.- From this mirror, reflection of the light: occunsthr ough either pinholes or small projecti'o'n' arrangements with the production of intense but very-small starimag'e's upon a dome even of large iadiiis. Thefofniafion ofthe sinall images is due to the fact that, viewed froni the position of a pinhole by 'refiec oh from a spherical miiror, the source appears greatly diminished iirisize. Eliectively, therefore, each phi-hole receives its". illumination from a virtual source which is minute even as compared with the apparent area of the source-.- Furtherhrore; by the arrangement which will be described, for all pra'tica'l purposes the illumination intensity is substantially uniform through a hemispherical region so that the star images themselves are only aitectd, as to intehsity by the" pinholes '01" other projecting elements from; which they issue. p

In accordance with the invention; furthermore; not 61313 may stars be projected but there may be prodiiced a highly satisfatory rendition of'the Milky Way:

The foregoing indicated general objects of the iri vntioh andothei' objects particularly relating to details will come" apparent from the following description; read in conjunction with the accompanying diawiiigs', in

Figure 1 is anoutline elevation showing the type at planetarin'mxprejector to which the invention may as appliedanli illfistrative of the problems ehcoiiiit'e'rdi' Figure 2 isa vertical section showing, in paiticular, the arrangement in a projector ofthe light source and res-set ing mirror;

Figure 3 is a section showing a projecting" lineiit particularly designed for the projectionof stafirnages of major magnitude and of the Milky Way, or the'lik'e;

Figure- 4 is a' sectional view showing the arm of aspherical refl'ectinginirror and associated echl'fiitg means; N

Figure 5 is aplan' view of the assembly sh'ov'vsia Figure 4; and

Figures 6; 7,- Sand 9" are diagrams 'illustfatiiig; in pa? ticular, the operation of theocculting s'y'ste'in';

, Referring first'to Figure i,- there is indicated at Z'fli floor of a planetarium and at- 4 portions of the dome vthereof; In thevicinity of the center of the do'nie' there is located "a projector which is desirably mounted; as shown in- Figure l, by guy wires 6 and 8 tens'ione'd By turnbuckles and servingto hold rigidly in: position a fiit'd shaft 'the ends of whichare" indicated at 10'; Each'of guy wires 6 andsillustrated' is representative of a of. guy wires diverging both in the-projection illustrated and in directions normal to the plane of the figure. In contrast with prior mountings" comprising heavy set-s1 frameworks, the guy wire mounting illustrated pr'odiices great stability of the instrument and,- at the seats time, a minimum of occulting of: the images projected as the dome. In practice it'has been found that as the pre ect ing; rays cross the guy wires the occultingpfoduce'dis quite unnotiseable: Ready access to the rejectsr is also attained by this construction and there is substantially no interference W'iththe viewing of the star images by those assembled in theplanetarium in contrast with the quite substantial obstruction p'resented byme massive mount-- ings heretofore used.

The-axis l-Zdefifid by the shaft 10 eiitends'inan east: west direction from the standpoint of the reproduction of thestar field. Mounted to rotate about the" aids 1-2 is a casting 14: The rotation about the aXis 12 provides change in latitude oflthe observation; The casting I4 ,imately 23 /2 in turn defines an axis 16 which rotates with it about the axis 12. The axis 16 represents the axis of the earth and is correspondingly designated by the letters N and S.

.Diurnal rotation is accomplished about the axis 16 by providing a central'assembly illustrated by the elements 18 and 20 which rotate within the casting14 about this axis. The central assembly defines in turn an axis 26 which moves with it and corresponds to the precessional platforms for the mounting of sun, moon and planet 7' projectors. These latter projectors are not illustrated 7 since they are not involved inthe subject matter of the invention herein claimed. For the purpose of general understanding, however, it maybe remarked that they project images in directions approximately normal to the axis 26 to simulate the apparent motions of the sun, moon and planets. Mounted at the outer ends of the

cages

22 and 24 are

hemispherical globes

28 and 30 which provide for the projection of the star images. These globes rotate about the axis 26 to illustrate precessional motion. It will be understood that in the complete planetarium, all of the motions above .mentioned are provided by motors under suitable controls. From the standpoint of the present invention, what is to be noted is that. the globes 28' have, essentially, universal angular motions requiring corresponding capabilities of the projection system to provide proper star images irrespective of the globe positions. Involved in this is also the matter of occulting star images which might otherwise be projected below the horizon. dome will normally be interrupted at the horizon, there being below thisa blacked-outarea which will not reflect the light from the images. Nevertheless, occulting of .images below the horizon is desirable to prevent the projected rays from reaching the eyes of the observers within the dome.

Reference may now be made particularly to Figures 2, 4 and 5. One of the globes, 28, is illustrated in Figure 2 associated with a light source assembly and a reflecting assembly. It is to be understood that precisely the same arrangement is provided in connection with the other globe 30 and only one need, therefore, be described- At the top of the globe 28 there is indicated a cover ,plate 32 which serves to mount the source assembly comprising the lamp'34 in which there is located an intense light source cathode area directed downwardly and indicated at 36. As will shortly become apparent, this source is required only to project its illumination downwardly, as viewed in Figure 2, through a small conical region and it has been found highly suitable to utilize for this purpose known arc-type lamps which provide small sources of the order of 0.3 millimeter diameter. Such a source is, in itself, very small, but by reflection is apparently even smaller so that as virtual sources of projection'there are substantially point sources. (The use of the plural in this connection will be justified hereafter.)

In order further to increase the intensity of illumination, there is provided in alignment with the source 36 a lens 38 mounted in a housing 40 which is adjustable .laterally in the lower end of a cage 42 and clamped in adjusted position by a locking nut 44. The cage 42 is provided with rods 46 slidably mounted in the cover plate 32 and secured at their upper ends in an externally threaded ring 48 surrounded by a nut 50. Springs 51 surround the rods 46 to urge the cage 42 downwardly, so that rotation of the nut 50, which continuously bears on the plate 32 under the action of the springs, serves to adjust the cage 42 and lens 38 axially to focus the beam from the source.

In line with the axis of the source 36 and lens 38 there is mounted a reflecting sphere 52 the center of which is desirably displaced toward the source from the center As is usual, the projection surface of the W of the globe 28. The beam of illumination from the source 36 is concentrated-by the lens 38 upon the reflector 52 and is reflected in all directions through somewhat more than a half a sphere so that rays pass through pinholes 54 in the surface of the globe, the pinholes being directed approximately radially toward the spherical reflector 52. Each pinhole 54 has essentially as its source of illumination a corresponding image of the light source as viewed by reflection from the spherical mirror. As

will be apparent from the optical system involved, the

virtual sources thus provided are essentially individual for the various pinholes, 'being found by each pinhole along an axis passing through a particular point of the spherical mirror, which point is individual to the pinhole. Thus, for the highest accuracy in projection, there must be considered the size of the spherical mirror, its displacement from the center of the globe 28, and also the parallax involved by the fact that the projector of *Figure 1 will have its globes olfset from the center of the dome. The layout of the pinholes 54 in the globe 28 is such as to allow for these conditions and provide a reason- "able compromise. Actually, the observer is not sensitive "to minor displacements of the stars with respect to each other and high accuracy of star positions is not required.

-It will be noted, however, that the spherical reflector 52 'is of small diameter with respect to the globe 28 so that for general descriptive purposes herein it may be considiered that the sources of illumination for the pinholes 54 are concentrated in the close vicinity of the center of the "reflector.

While various occulting arrangements may be used, :there is illustrated herein a practical occulting arrangeimerrt which constitutes the subject matter of an application of George Vaux, Gilmore L. Stitely and George A. "Smith, Serial No. 483,644, filed January 24, 1955. The 'object of this occulting arrangement, or of such other iocculting arrangement as may be used, is, in particular, to prevent to a substantial extent the projection of beams -.of light from the projector into the eyes of observers. 0 .For this purpose, the occulting means reduces to a great extent the probability that any rays will be projected ,from the globes below a horizontal plane through the projector.

Secured in the corresponding cage 22 there is a shaft.

:60 extending along the axis 26 on which thereis mounted by means of ball bearings 62 and 64 a U-shaped bracket .66 supporting at the upper ends of its arms pins 68 which project inwardly and carry mounting'elements 70' and.

. 82 and 84 mounted on pins carried by the'members and 72 and which, in turn, mesh with

pinions

86 and 88, respectively, journalled upon the'pins 68. Secured to the hubs of pinions 86 =and 88 are

sleeves

90 and 92 which are, respectively, connected to

arcuate plates

94 and 96 to which are secured heavy

arcuate members

98 and 100 which are connected together below the spherical mirror by a heavy yoke member 102. The

pinions

78 and 80 have twice the number of teeth of the

pinions

86 and 88. By reason of its pendant weight, the assembly comprising the

members

94 and 96 and 98, 100 and 102, acts as a pendulum mounted on the common axis ofthe pins 68. Accordingly, as the position of the fixed shaft 60 changes, the pendulous assembly just mentioned retains its position with respect to the vertical, the bracket 66 swinging about the axis of shaft 60 to maintain this condition, In other .words, the pendulum swings about 75 an axis which is constantly horizontal and perpendicular to the plane of inclination of the axis 26 with respect to the-verticalQ Consideration of the operation, therefore, may be reduced to consideration of what occurs as the axis of shaft 69, -i. e. 26, is considered as tilting about a horizontal axis. As such motion takes place, the lamp source 36 correspondingly moves. At the same time, the sphere 52 rotates about its axis in the same angular direction but at half the angular velocity of the rotation of the axis 26.

The spherical reflector 52 is provided with a pair of non-reflecting zones 198 and 110. These zones are circular in outline and subtend at the center of the sphere angles of 90. The two zones are diametrically opposite each other and their common axis is perpendicular to the axis of shafts 56 and 58 and is horizontal when the shaft 60 is vertical. As will be seen from Figure 4, the upper edges 106 of the

members

94 and 96 are horizontal and located at a level approximately midway between the center of the reflecting sphere and its top. Between the members 94- and 96 are gaps provided by their edges 104, and these gaps are of a width corresponding to the chord subtended by an angle of 90 at the surface of the spherical mirror. As will become apparent, these gaps are required topermit incident light to strike the mirror under certain conditions to provide reflection therefrom through regions extending to 90 from the direction of incidence.

The nature of the projecting and occulting systems will become. clearer from consideration of Figures 6 to 9 which show the paths of incident and reflected. rays in a plane perpendicular to the axis of the shafts 56 and 58. While reflections out of that plane are involved, their nature will be generally evident from consideration of the rays in the plane.

Figure 6 shows the conditions which exist when the axis 26 is vertical with the source 36 directly above the mirror 52. A central incident ray is indicated at I Limiting incident rays 1 and I produce horizontal reflections R and R (The rays I and- L; are shown as parallel though they may be slightly convergent due to the action of lens 38.) The rays R and R are the limiting desirable rays, and it will be noted that they are reflected from points at the upper extremities of the non-reflecting zones 1G8 and 110. Occulting in the plane illustrated thus is the result of these zones. In other directions, the occulting is effected by the upper edge 106 of each of the

members

94 and 96. The occulting thus effected permits rays slightly below the horizontal. This is desirable, however, because in the position illustrated the uppermost globe may be somewhat above the horizon of the dome.

Passing to Figure 7, it may be assumed that the axis 26 has tilted counterclockwise so that the incident rays are as indicated at I i and i It will be noted that the reflections R and R now take place at the upper edges of the zones 198 and 110 which have moved through an angle equal to half the angle alpha of inclination of the axis 26. The purpose of the half speed angular rotation of the spherical reflector will now be apparent: this insures a proper rotation to provide the horizontal cut-ofi'.

Figure 8 illustrates still further counterclockwise rotaltion of the axis 26. The incident rays are 1 I and I and the limiting horizontal reflected rays are R and R It may be noted, however, that the ray R under these conditions would not pass through any openings in the globe 28 but, rather, would be arrested by its bottom which is closed, though not illustrated as such in Figure 2, and is perpendicular to the axis 26. Somewhere between the positions of Figure 6 and Figure 8, therefore, depending upon the particular dimensions involved, the non-reflecting Zone ill) will lose its useful occulting function.

Figure 9 shows a further rotation of the axis 26 to the extent that the incident rays are directed upwardly.

The central ray is I .1 shows the incident ray which produces a horizontal reflection R Both the incident and reflected rays pass through the gap between the edges 104, and this condition illustrates, therefore, the necessity for this gap. Occultin'g below the horizontal reflection is still produced by the zone 168; The incident ray 1 shown in Figure 9 is approximately the outermost ray which produces a useful reflection R since the closed bottom ofthe globe will occult reflected rays clockwise of this.

Continued rotation would produce results corresponding to those already described; It will, furthermore, be evident why two zones 108 and are required since they effectively alternate their positions in a single rotationof the axis 26.

The foregoing has not described what happens in the case of rays producing reflections out of the plane dis cussed. However, it will; be evident that occulting of these rays takes place dueeither to the edges 106 or the zones 108 and 116. To produce precise horizontal occulting under all conditions, it will be found that, theoretically, the edges of the zones'108 and 110 would have to change shape during the rotation. While this might Well be accomplished by providing variable equivalents of these zones separate from the spherical reflecting surface but adjacent thereto, the complications of achieving this end are not warranted by practical considerations. With the arrangement illustrated, rays passing through the openings corresponding to particular stars will sometimes be directed below the horizontal. The probability that such a ray will reach an observers eye or that it will persist for any objectionable durationof time is'so small as not to warrant a greater complexity of the occulting mechanism. Furthermore, it will be noted that the stars in the vicinity ofthe plane of the ecliptic might well be projected fromeither ofthe globes. This is due to the fact that the reflecting mirror 52' is displaced from the center of each globe. Due to this, the star holes may be located where there is a minimum likelihood of objectionable non-occultation. For all practical purposes, therefore, the occulting system is completely satisfactory.

As will be evident from the foregoing, each pinhole 54 views as its virtual source of light a minute source which, for practical purposes, is substantially a geometrical point. The size of the pinhole defines the size of the image projected on the dome taking into account the respective diameters of the globe and dome. To a great extent, therefore, the stars of lesser magnitude may well have their intensities adjusted merely by choice of size of the pinholes. In this fashion, different size images are produced which, by reason of differences of size, have different apparent intensities.

However, particularly in the matter of first magnitude stars, greater intensities of the images are desired than can be satisfactorily produced while keeping down the sizes of the images. Accordingly, it is desirable to provide projecting assemblies in place of pinholes in the cases of such stars as illustrated in Figure 3. Each of these assemblies comprises a tube 112 fitted in an opening in one of the globes and threaded externally at its outer end to receive a clamp ring 114 which holds in assembled relationship a lens 116 of suitable focal length, an aperture plate 118 provided with a central aperture 120 and, in some cases, a filter 122 which may be colored to give the proper hue to the star involved. By the use of this arrangement, the total intensity of light passing through the aperture 120 may be focused on the dome to produce a satisfactorily small image. In such case, therefore, the apparent intensity is actually due to an increase of intensity of illumination rather than merely an increase in size of the image.

It is found, furthermore, that by the use of a film transparency in the position illustrated at 122 provided solid angle.

Way. .Other patches of light may be provided to indicate nebulae, globular clusters, Magellenic clouds, and

the like.

It will be evident that even if a filament source of illumination is used, the spherical mirror reflecting arrangement will produce a minute virtual source for projection even if the filament source is fairly large; Furthermore, di-

rectional characteristics of the source are unimportant since all of the rays utilized are located within a small By reason of the latter situation, however, much of the radiation from a filament source would be wasted as heat, and for efliciency, an arc-type source is desirable as above described.

It may be noted that the arrangement described for producing a minute virtual light source may be used in other devices than planetaria Where such light sources are required for projection or other purposes. 7

It Will be evident that various matters of detail may be changed Without departing from the invention as defined in the following claims.

What is claimed is:

1. A projector comprising a substantially hemispherical perforated globe, a spherical mirror positioned radially centrally of said globe, and a high intensity light source in the zenith position within said globe above said spherical mirror directing light rays to said spherical mirror from which they are reflected to said globe passing through perforations therein, said light source and spherical mirror providing virtual light sources for each 'of the perforations in said globe of eflective size smaller than said high intensity light source.

2. A planetarium projector comprising a substantially hemispherical opaque globe having openings therein, a convex mirror positioned approximately centrally of said globe, and a high intensity light source in the zenith position within said globe above said mirror directing light rays to said mirror from which they are reflected to said globe passing throughopenings therein, said light source 1 and mirror providing virtual light sources for each of the openings in said globe, said light sources being of efiective size smaller than said high intensity, light source.

3; A planetarium projector comprising a substantially hemispherical opaque globe having openings therein, a

convex mirror positioned approximately centrally of said globe, a high intensity light source in the zenith position within said globe above said mirror directing light rays to said mirror from which they are reflected to said globe passing through openings therein, said light source and mirror providing virtual light sources for each. of the openings in said globe, said light sources being ofeffective size smaller than said high intensity light source, and some .of said openings having members provided with lenses in alignment therewith receiving rays from said virtual light sources and directing them through a surface externally of said globe.

References Cited in the fileof this patent UNITED STATES PATENTS 1,616,736 Bauersfeld Feb. 8, 1927 1,693,969 Villiger et al. Dec. 4, 1928 2,077,111 Kent Apr. 13, 1937 2,168,799 Korkosz et al Aug. 8, 1939 2,178,352 Unglaube et al Oct. 31, 1939 2,299,682 Conant Oct. 20, 1942 2,304,434 Ayres Dec. 8, 1942 2,393,310 Crane Ian. 22, 1946 2,448,568 Zwillinger et al. Sept. 7, 1948 2,483,216 Marshall Sept. 27, 1949 2,632,359 Spitz Mar. 24, 1953 2,682,803 Korkosz July 6, 1954 FOREIGN PATENTS 707,877 Great Britain Apr. 28, 1954